Process and Device for Manufacturing a Dental Restoration

ABSTRACT

Methods for manufacturing a dental restoration for a patient and dental ceramics production devices are disclosed. A dental restoration may be designed based on a scan of the patient&#39;s mouth, using a CAD software module. The software module may produce conveyor channels for a positive model based on the dimensions of a muffle in relation to the size and shape of the positive model. The conveyor channels may extend at an angle of between 0° and 130° away from an axis of the pressing channel, the axis being located essentially along an isotherm inside the muffle. A docking site may be selected based on a position with the greatest wall thickness of the positive model. The present disclosure allows the creation of a high-quality dental restoration in a very efficient fashion, in particular when lithium disilicate is used as the dental ceramics material.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No.14/732,547, filed Jun. 5, 2015, which claims priority to EuropeanApplication No. 14171268.7, filed on Jun. 5, 2014, now pending, theentire disclosures of which are incorporated herein by reference.

FIELD OF THE DISCLOSURE

The disclosure relates to a process for manufacturing a dentalrestoration as well as a dental ceramics production device.

BACKGROUND OF THE DISCLOSURE

Expendable molds have previously been used to manufacture dentalrestorations. For example, a positive model of the dental restoration isfirst manufactured in a suitable fashion in accordance with thepreferences of a dental technician or a dentist. The positive model ismade out of wax or out of another substance, such as a polymer, that canbe incinerated without leaving residues.

The positive model is then connected with what is referred to as amuffle base via a conveyor channel which can, for example, comprise thesame material as the positive model of the dental restoration as apin-shaped element. This muffle base comprises a disc made from aplastic material, from which a peg-shaped projection rises up whosefront surface is used as the base of the conveyor channel.

After the positive model has been applied together with the conveyorchannel, a small radius can also be attached at the transition betweenconveyor channel and dental restoration on the one hand, and the frontsurface of the muffle base on the other hand, respectively, which isusually referred to as merging.

A silicon ring is then slipped over the disc-shaped muffle base, whichis provided with a recess, and a self-hardening casting compound is castinto the inside space thus formed. This can, for instance, comprise ofplaster or other suitable materials.

After hardening, the silicon ring is removed or rolled off, and themuffle base is pulled off. In this process, the connection between thefront surface and the conveyor channel (or channels) is loosened whilethe wax components still remain in the hardened muffle.

The muffle is then heated to a temperature that makes it possible toremove the wax components without any residues being left behind. Thiscan happen in what is referred to as a pre-heating furnace, for example,that provides a temperature of 700° C.

Subsequent to this, the muffle with the cavity or cavities which nowremain in place of the positive model is turned around, such that thechannel that corresponded to the peg of the muffle base lies free ontop. This channel is at the same time the pressing channel, and a blankmade of a material, such as a dental ceramics material, is inserted intoit which is suitable for shaping the dental restorations.

A pressing furnace is provided with a pressing plunger which enters intothe pressing channel and further heats up the blank together with themuffle in accordance with a predetermined pressing program, for exampleto a range of 1100° C. in case of a silicate or feldspar ceramicmaterial, or to 1600° C. in case of an oxide ceramic material.

In accordance with an exactly predetermined pressing program, pressureand heating are controlled in unison with each other, such that theblank enters the cavity or the cavities via the conveyor channels whenmelting, and there the dental restoration is produced, if possiblewithout any bubbles.

The process described above has been known for at least 30 years and isin wide-spread use today.

Recently, it has been practiced in many cases to take a scan of thepatient's mouth for manufacturing the positive model, and via softwarethe desired dental restoration is designed and produced.

It has also been suggested to use an additive process for the productionof the positive model after the computer-controlled molding, forexample, to produce the positive model by means of rapid prototyping. DE103 32 802 A1 describes one such example.

Such rapid prototyping processes, which are basically suitable fordental technology with respect to resolution, such as for instancestereolithography, have also been known since the 1980s.

In the field of dentistry, the use of the technology of rapidprototyping for the manufacturing of models has at least been known forabout 20 years and is shown, for example, in WO 95/28688 A1 in which thepositive model technique mentioned above is also disclosed.

Despite the advantages of computer-assisted design, which have beenknown for quite a long time, this technology has not gained universalacceptance.

It has also been suggested to produce the dental restoration, instead ofmanufacturing it by means of pressing, with the help of a castingprocess. This technology too has been known for a long time.

It has been suggested to produce a positive model with the help ofcomputer assistance, in an additive fashion in order to thus avoid thenecessity of the step of milling. In this suggestion, during milling,complex inside corners can only be created with great difficulty. Thecasting of a mold cavity in a muffle makes it possible to provide thedental restoration at a central position inside the muffle. At thisposition, the muffle usually has a rather low temperature gradient,because the muffle is typically heated by a heater which annularlysurrounds it, and if necessary, an additional heater is provided fromunderneath as well. In the outer portions of the muffle, the temperaturegradient is usually considerably larger, especially with the fastheating of the muffle by the dental furnace which is aimed at themuffle.

The production of the dental restoration thus suggested, however, hastwo major disadvantages: First, in case of a central arrangement, onlyone single dental restoration can be produced with the help of a muffle,which is extremely inefficient. Second, the quality of the surface islacking in comparison to pressed dental ceramics.

BRIEF SUMMARY OF THE DISCLOSURE

In contrast, the present disclosure allows the creation of ahigh-quality dental restoration in a very efficient fashion, inparticular when lithium disilicate is used as the dental ceramicsmaterial.

One embodiment of the present disclosure can be described as a methodfor manufacturing a dental restoration for a patient. The methodcomprises designing a dental restoration based on a scan of thepatient's mouth, using a CAD software module. The method furthercomprises producing a positive model of the dental restoration using amaterial that is removable from a mold without leaving a residue. Themethod further comprises producing, using the CAD software module, atleast one conveyor channel for the positive model based on thedimensions of a muffle in relation to the size and shape of the positivemodel, wherein the conveyor channel is determined by defining a spacewithin the muffle for arrangement of the dental restoration. The methodfurther comprises removing the positive model using the muffle, whereinthe muffle has a pressing channel which is connected via a conveyorchannel with a cavity for the dental restoration corresponding to thepositive model. The method further comprises inserting a blank of dentalmaterial into the pressing channel. The method further comprises heatingand applying pressure to the blank such that the blank is deformed anddental material for shaping the dental restoration flows through theconveyor channel and fills the cavity. In this embodiment, the conveyorchannel extends at an angle of between 0° and 130° away from an axis ofthe pressing channel, the axis being located essentially along anisotherm inside the muffle. In addition, a docking site is selectedbased on a position with the greatest wall thickness of the positivemodel, and the CAD software module positions the positive model inrelation to the conveyor channel to elongate the axis of the conveyorchannel and that the length of a virtual axis through the positive modelis maximized.

In one embodiment, the CAD software module determines, based on theshape of the positive model, starting from the position with thegreatest wall thickness of the positive model, a primary flow directionfor the dental material in which the cross-section of the flow in apre-determined distance from the thickest position is greatest, and thatthe maximized virtual axis through the positive model deviates in theprimary flow direction.

In another embodiment, the arrangement of the dental restoration withinthe muffle are determined by the CAD software module in such a fashionthat the greatest longitudinal extension of the dental restorationessentially extends along an isotherm.

In one embodiment, if a plurality of dental restorations aremanufactured at the same time, the plurality of dental restorations arepositioned essentially along the envelope curve of a cone or taper andequally spread around the pressing channel which essentially terminatesat the peak of the cone or taper.

In another embodiment, the method of claim 1, wherein the conveyorchannel is provided with radii and/or constant transitions in thedirection towards the pressing channel, and in the direction towards thedental restoration.

In one embodiment, the conveyor channel determines the alignment of thedental restoration, and an alignment of the dental restoration isdetermined such that a penetration length of the conveyor channelthrough the dental restoration is maximized.

In another embodiment, the dental restoration is formed as a crown or abridge and the basal area of the crown extends in elongation of apressing channel axis with an open side away from the pressing channel.

In one embodiment, the dental restoration is formed as a prefacette or aveneer and the basal area of the prefacette or the veneer extends suchthat it points radially outwards in relation to a pressing channel axis.

In another embodiment, an alignment of the dental restoration withrespect to the conveyor channel axis is selected such that theelongation of the conveyor channel axis through the dental restorationextends through the center of mass of the dental restoration when theconveyor channel axis is positioned at the thickest position of thedental restoration.

In one embodiment, the CAD software module connects the conveyorchannel, in relation to the outside surfaces of the dental restoration,in an eccentric or off-center fashion.

In another embodiment, the length of the conveyor channel is determinedby the CAD software module depending on the size and the weight of thedental restoration.

In one embodiment, if a number of dental restorations are arranged inone muffle, the CAD software module determines the conveyor channels tothe dental restorations such that the dental restorations are arrangedat regular intervals within an isothermal corridor such that thearrangement of dental restorations approximates a taper or cone.

In another embodiment, the CAD software module accesses a conveyorchannel library which indicates different profile designs, lengths,docking points and angles of conveyor channels based on sizes and typesof dental restorations, and that the CAD software module, based on thesevalues, determines or suggests the conveyor channels with regards totheir lengths, their diameters, and their angles.

In one embodiment, the virtual inside is dependent on the size of themuffle and releases a placing space of the dental restoration within themuffle such that the dental restoration keeps a distance from the muffleof at least 2 mm with respect to the outside wall of the muffle and theheight of the virtual inside space is lower in a radially inwardlydirection than in a radially outwardly direction.

In another embodiment, the positive model is manufactured by a millingprocess and a milling blank is formed as a cylinder with a cylinderheight corresponding to the virtual space of between 15 mm and 50 mm.

In one embodiment, at least one conveyor channel is formed as a dummychannel without an associated dental restoration.

In another embodiment, the length and thickness of each conveyor channelrelative to the other conveyor channels is selected such that it isadapted to the volume of its associated dental restoration.

The present disclosure may also be described as a dental ceramicsproduction device. The device may comprise a CAD/CAM device forproviding a pressing mold for manufacturing a dental ceramics. Thedevice may further comprise a CAD software module executed by theCAD/CAM device.

The CAD software module may be configured to determine the shape of adental restoration, based on a scanning result of a mouth of a patient.The CAD software module may be further configured to determine theconfiguration of the dental restoration using an expendable muffle. TheCAD software module may be further configured to determine thearrangement of an angle and dimensions of a conveyor channel between acentral pressing channel and a cavity for shaping the dental restorationinside a virtual inside space within the muffle. The CAD software modulemay be further configured to determine the work angle of the dentalrestoration in relation to a conveyor channel axis of the associatedconveyor channel at a docking site of the dental restoration at theconveyor channel, the docking site positioned at the thickest positionof the dental restoration, such that an elongation of the conveyorchannel axis extends through the largest possible length of the dentalrestoration starting from the thickest position, in particular based ona pre-set library of shapes of dental restorations and/or conveyorchannels.

In one embodiment, the docking site of the dental restoration at theconveyor channel is selected by the CAD software module at the positionat which a ball with the largest possible diameter fits into the dentalrestoration, wherein an elongation of the axis of the conveyor channelextends in particular essentially through the center of this ball.

In another embodiment, each dental restoration is determined by the CADsoftware module in the virtual space with regards to its arrangement andalignment such that it has a marginal distance both from the outsidewall of the muffle and from the neighboring dental restoration whichdoes not exceed a pre-determined value.

In one embodiment, the docking site of the dental restoration at theconveyor channel in a vertical projection in relation to the muffle isselected in such a fashion that a narrow position of the dentalrestoration is arranged radially inwards and a wider position furtheroutside radially.

In another embodiment, the conveyor channel and/or the dentalrestoration is provided with a code or an identification at a basal or acovered position, which facilitates the association with the orderconcerned and/or the patient concerned.

In one embodiment, wherein the dental restoration is provided with aconstant and layer-by-layer construction which is suitable forstereolithography, in particular with an envelope curve whose slope isalways larger than or equal to zero over its entire extension fromdocking site of the dental restoration in the lateral view or observedin the direction of the pressing channel axis.

In accordance with the disclosure, the dental restoration may beproduced in a virtual space inside the muffle using a special CADsoftware module for the production of the positive model of the dentalrestoration and determine the position in accordance with particularcriteria. An embodiment of positive models suitable for a multitude oftooth shapes and types of dental restorations may be created such thatthe models extend over the conveyor channels in a fashion resembling atree. The pressing channel insofar basically forms the trunk of this“tree”, and the conveyor channels form the branches at the top of eachof which one dental restoration is usually provided. Preferably, boththe conveyor channel and the dental restoration itself extend with theirmain axes, respectively, along an isotherm, which leads to lowertemperature gradients within the cavity for the dental restorationduring the process of pressing.

As a result of the automatic production of the conveyor channel and thedental restoration, faults, which have often lead to compensation claimsagainst the producers, can be reduced, and also the number of dentalrestorations produced at the same time can be increased.

For example, using the present disclosure, it is possible to define aminimum distance between neighboring dental restorations, such as 3 mm,and to position the dental restorations with the help of the positivemodels produced by means of rapid prototyping in such a fashion thatthey are displaced in space in relation to one another, on differentlevels, and in a circle, without there being the risk of a deteriorationin quality. The “multiple-layer arrangement” of dental restorationsresulting can be advantageous, in particular, with newer pressingfurnaces which are provided with underneath heating for the muffle, as aresult of which the isotherms of the muffle extend in a differentfashion than with a mere annular heating.

In accordance with the disclosure, it may be advantageous that thepressing process can be enhanced with a number of dental restorationscreated in parallel. For example, the flow resistance of the heatedceramic material which is used for creating the dental restoration canbe adapted by means of dimensioning of the respective conveyor channel.

The adaptation may be put into practice in such a fashion that thedental restorations (i.e., the corresponding cavities in the muffle) arecompletely filled at the same time. With smaller volumes of the dentalrestoration, one will correspondingly have a thinner or longer conveyorchannel produced by the module, and will vice versa, with a bridge witha number of segments of a correspondingly large volume, have theconveyor channel or the conveyor channels put into practice shorter orthicker.

While the prior art teaches away from producing different dentalrestorations in the same pressing step, in particular with silicateceramics, it is possible without any problems in accordance with thedisclosure, to produce at the same time even very large and very smalldental restorations, which further contributes to an increase inefficiency. For example, restorations made out of lithium disilicatehave a very low shrinkage, and can thus be provided in a particularlyquick and economic fashion.

The measures of the alignment of the dental restoration (and the cavityand the positive model, each respectively) in accordance with thedisclosure include the selection of the position with the largest wallthickness of the dental restoration as the docking site of the conveyorchannel at the dental restoration, and then aligning the dentalrestoration in such a fashion that its longitudinal axis corresponds tothe axis of the conveyor channel. This measure results in a dentalrestoration which can be produced particularly favorably which makes itpossible to produce the positive model additively by means of rapidprototyping, for instance with the help of stereolithographic processes,and also in the absence of any bubbles.

When casting the positive model with the help of liquid castingmaterial, such as plaster, there is regularly the risk of cavitiesremaining which are not filled by the casting compound; the riskexisting insofar is minimized by the alignment in accordance with thedisclosure.

On the other hand, there is the risk in the process of pressing thatbubbles remain in the ceramic material which entail a deterioration ofquality. By using the inclined arrangement in accordance with thedisclosure in combination with the feature mentioned above, this risk isminimized as well in accordance with the disclosure.

The conveyor channel may extend in an inclined fashion away from thepressing channel and its axis and extends insofar in an inclined fashionthrough the muffle, since the axis of the pressing channel regularlycoincides with the axis of the muffle arbor.

In accordance with the disclosure, it is also intended to adapt theinclination in a certain way to the type of heating of the muffle. Incase the muffle is heated from underneath, the overall possible angularrange of between slightly more than 0° and 120° or 130° in relation tothe axis of the muffle or the pressing channel, respectively, isavailable. In the case of an annular heating, in contrast, for example,the axis may be kept at an angle of between 40° and 65°, based on thenarrower area of the isothermal corridor.

In accordance with the disclosure, the virtual inside space can bedetermined as a result of the predetermined limits of distance, i.e. apredetermined distance to the pressing channel and a predetermineddistance to the outer wall of the muffle, and also upwards anddownwards, within which limits the module has to arrange the dentalrestorations including the conveyor channels. As a result of that, it ismade sure that the muffle does not crack due to too low wallthicknesses, and also that the marginal conditions with regards toisothermality are adhered to.

In this connection it is to be understood that the possible matching oftemperatures within an area referred to as being isothermal stronglydepends on the ceramic material to be pressed. For instance, feldsparceramics can have a larger range of isothermality or range of paramoithermality, i.e. a range of similar temperatures, than lithiumdisilicate ceramics. Also these marginal conditions can be taken intoaccount with the help of the CAD software module in accordance with thedisclosure, such that a displacement of levels with the correspondingcompaction of the arrangement of dental restorations observed in atangential direction not only in case of heating from underneath, butalso depending on the material.

In accordance with the disclosure, the arrangement may be automaticallyadapted as well as the number of conveyor channels to the type andnumber of dental restorations. If, for example, a bridge of eightsegments with three conveyor channels which end each at the respectivethickest position of the corresponding teeth are selected as the dockingsites and extend in a slightly curved fashion, the inside space of thecurve thus produced can be used for placing another dental restorationtogether with the corresponding conveyor channel within the virtualinside space.

In one embodiment, it is intended that the alignment of the dentalrestorations can be modified in such a fashion that it extends in anelongation of the conveyor channel axis, which is essentially with themaximum length of the virtual axis through the positive model, howeverslightly tilted in the direction of the primary flow direction, i.e. inmost cases in the occlusal direction. This leads to a slightly lowerdegree of re-direction of the flow at the docking site, which furtherreduces the tendency to form bubbles. For instance, the re-direction ofthe primary flow direction out of the conveyor channel can thus bereduced from 30° to 20°, such that the dental restoration is positionedin such a fashion that it is tilted by 10° in relation to the maximumlength of the virtual axis.

In another embodiment it is intended that the dental restorations arepositioned around the pressing channel, but still slightly spaced apartfrom its front surface. Between the front surface and the dentalrestorations, the conveyor channels then extend (which are determinedeach by the CAD software module) and the module spreads the dentalrestorations preferably in a uniform fashion in this area in an inclinedfashion in front of the front surface of the pressing channel. Thedental restorations and conveyor channels may essentially form a taperor a truncated cone insofar, with the front surface as the truncatedcone or tapered surface, and extend only slightly, still in the area ofisothermality, outside the taper surface.

An axisymetric arrangement of the muffle and the pressing channel may beused in accordance with the disclosure, and may be used to achieve animproved result of the pressing process based on the embodiment inaccordance with the disclosure. However, the muffle is not restricted toa cylindrical muffle. Muffles according to the present disclosure mayhave other shapes, for example, a muffle may be pear-shaped whenobserved from the side, or may be cloverleaf-shaped when observed fromthe top, etc.

As a result of the constant transitions or radii between the conveyorchannels and the pressing channel, which are intended in one embodiment,on the one hand and also the dental restoration on the other hand it isprevented that muffle material existing there is subjected toexcessively high pressure during the pressing process and accordinglycracks. Such flow transitions may be advantageous as far as the flow isconcerned and reduce the counter pressure in pressing during the shapingprocess to the necessary minimum amount.

As an additional issue for the alignment of the dental restoration, i.e.the selection of the docking site, the CAD software module can take intoaccount that the passage length through the dental restoration may bemaximized. For this purpose, the CAD software module creates theshortest vector to the position of the dental restoration farthest awayfrom the docking site and maximizes this length for the exact selectionof the docking site.

The alignment of the dental restoration relative to the conveyor channelaxis is then selected in such a fashion that an axis between the centerof the docking site and the remotest point of the dental restorationform a virtual axis which extends in elongation of the conveyor channelaxis.

Also this arrangement can be displaced slightly in the occusal/incisaldirection, for example by 10° or 15°, in order to reduce there-direction of the flow.

It is furthermore intended in accordance with the disclosure to alignopen surfaces, i.e. surfaces in proximity of the basal surface, of thedental restoration radially outwards with relation to the pressingchannel axis. This may avoid the formation of small bubbles and alterthe effect of temperature gradients.

In one embodiment, the center of mass at the thickest position of thewall of the dental restoration can also be of assistance in determiningthe angle orientation of the latter in relation to the conveyor channelaxis. the dental restoration can be aligned in such a fashion too thatthe elongation of the conveyor channel axis extends through that.

In another embodiment, it is intended that the CAD software moduledetermines the length of the conveyor channel depending on total weight.Here, the length of the conveyor channel may amount to distinctly lessthan the length of the main extensional direction through the dentalrestoration, and amounts—depending on its size and weight—to between 30%and approximately 70% of the length of the main extensional direction.

The conveyor channels can also be stored in a library, and the CADsoftware module can then select which of the conveyor channels from thelibrary existing in advance will suitably be employed.

While for the realization of the positive model, the production by meansof rapid prototyping can be used, for instance with the help ofstereolithography or of FDM, it is also possible in case of structuresof easier design which are less complex, to produce the positive modelby means of computer-controlled milling. In this, blanks, for examplemade out of a polymer, polyacrylics or wax, can be employed which arerealized in the shape of discs with a height of 20 mm or 25 mm.

Instead of this “pancake” cylinder, an upright cylinder can also be putinto practice as a milling blank, which can then have a height of 50 mm,for instance.

In accordance with the disclosure, with the help of a correspondingfurnace-related specification, the CAD software module can provide anangle corridor for the realization of the dental restorations, whichmakes it possible to always place the dental restorations within anisothermal corridor. The virtual space predetermined insofar is moreoverpredetermined in the horizontal direction by a minimum marginal distanceof, for example, 10 mm to the outer wall of the muffle, and also to thepressing channel, which corresponds to the muffle arbor. For the moreprecise setting of the conveyor channel, the CAD software module takesinto account in particular also the volume of each associated dentalrestorations and thus sets the length and thickness of the conveyorchannel based on this. In addition, the size of the muffle can bedetermined based on the number of dental restorations to bemanufactured, wherein the standard sizes of 100 g, 200 g and 300 g ofmuffles of corresponding known dimensions can be kept ready.

In one embodiment, it is intended herein with only very few dentalrestorations to be produced to put into practice a conveyor channel as adummy channel. This channel serves for the purpose of damping an abruptincrease in pressure towards the end of the pressing process in order tofurther reduce the risk of the muffle cracking.

In another embodiment, it is intended to provide the base of theconveyor channel in a standardized fashion. This can have a projectionwhich positively engages with the muffle arbor and is stored in theconveyor channel library as the zero point of the virtual inside spacefor providing the conveyor channels. For example, the muffle base (i.e.the muffle peg projecting from the disc-shaped base) can be providedwith a central recess which positively accommodates the correspondingprojection of the conveyor channel base.

At the conveyor channel base, the conveyor channel or the multitude ofconveyor channels is then preferably built up. The conveyor channel baseis insofar a disc which is provided with a positive-connection element,for instance a projection, which can be engaged with the muffle arbor,or makes possible another connection.

Alternatively, an apron can also be provided at the outer circumferenceof the conveyor channel base, which encloses the muffle arbor.

From the upper surface of the conveyor channel base, the conveyorchannel or channels extends away laterally in an inclined direction. Theangle of the conveyor channel axis is put into practice in accordancewith the above defaults, and the desired marginal distances (i.e. thedistances between the dental restorations on the one hand and themargins of the muffle on the other hand) can be set with the help of theselection of the place of the starting point of the conveyor channel onthe conveyor channel base determined in accordance with the defaults.

If the conveyor channel is in a position inclined by 45°, for instance,the vertical position of the dental restoration can be increased in thatthe starting point of the conveyor channel is displaced radiallyinwardly. As a result of this, the conveyor channel is virtuallyautomatically (provided the angle is constant) elongated. Theflow-related effects of this elongation can, however, in turn becompensated by enlarging the diameter of the conveyor channel, inaccordance with the disclosure.

Based on the conveyor channel angle optimized with regards to theisothermal corridors, the dental restorations can accordingly and inaccordance with the disclosure have alternating larger and smallervertical heights, observed from the side, in order to thus provide aspace-optimized tree of dental restorations

DESCRIPTION OF THE DRAWINGS

For a fuller understanding of the nature and objects of the disclosure,reference should be made to the following detailed description taken inconjunction with the accompanying drawings, in which:

FIG. 1 is a schematic view of a positive model of a dental restoration,together with the conveyor channel which was already automaticallyproduced by a module of a CAD software, which conveyor channel emanatesfrom a pressing channel;

FIG. 2 is a modified embodiment of the positive model of the dentalrestoration in accordance with FIG. 1, with a different angle of theconveyor channel;

FIG. 3 is a third exemplary version of a dental restoration or apositive model, respectively, which is manufactured by means of applyinga process in accordance with the disclosure;

FIG. 4 is a modified embodiment of the production in accordance withFIG. 3;

FIG. 5 is a schematic depiction of a positive model equipped withconveyor channels for use in a dental restoration production device inaccordance with the disclosure;

FIG. 6 is another depiction of a positive model for use in a dentalrestoration production device in accordance with the disclosure;

FIG. 7 is a schematic depiction of the alignment of the positive modelin a process in accordance with the disclosure;

FIG. 8 is a schematic depiction of the alignment of another positivemodel and additionally its position in virtual space; and

FIG. 9 is a schematic depiction of another positive model and itsconveyor channels, including their position in virtual space.

DETAILED DESCRIPTION OF THE DISCLOSURE

In FIG. 1, a positive model 10 of a dental restoration 12 is depictedtogether with its position in space. As can be seen, an axis 14 of aconveyor channel 16 extends straight through positive model 10, startingfrom a muffle arbor 18 or a pressing channel 20, respectively, or, to bemore precise, starting from their front surface 22, which is at apredetermined angle to an axis 24 of muffle arbor 18 or pressing channel20, respectively, which here amounts to 45°.

With the help of this depiction, one embodiment of the process inaccordance with the disclosure can be explained.

For putting into practice one process in accordance with the disclosure,the position of the tooth of the dental restoration is, or the positionsof the teeth of the dental restorations are, first recorded. Thisincludes the position of the tooth inside the mouth, i.e. for example21, 22 etc., additionally the type and number of dentalrestorations—i.e. for example bridge, crown, inlay, veneer, prefacetteetc.—and also the pressing conception. This also includes the pressingprogram for the subsequent pressing process in the pressing furnace;this is selected in the dental restoration production device inaccordance with the disclosure with the help of a menu item. With thisselection, it is possible to optionally determine whether the dentalfurnace is, for instance, provided with annular heating or additionalunderneath heating for the muffle, each of which comprises differentangle defaults of angle 30 from axis 14 to axis 24.

Based on this pressing concept, a corresponding library of conveyorchannels—including their possible angles—is additionally offered.

With setting the pressing concept, the selection of materials of theceramics to be used (for example oxide or silicate ceramics) results aswell.

Before or possibly also after these determinations, the dentalrestoration may be determined in such a fashion that it matches itsneighboring teeth in their shapes, arrangement inside the oral cavityand so on, based on a digital scan of the patient's mouth. From this,the volume of the respective dental restoration is automaticallycalculated, from which also the overall volume of the dentalrestorations results which are to be produced at the same time inaccordance with the disclosure.

Also the position of the dental restoration in relation to theneighboring teeth may be determined by the CAD software, i.e. in amesial/distal direction, in an occlusal/cervical direction, in therotational position around the tooth axis and so on. This also includesthe development of the wall thickness of the dental restoration and thepositive model, respectively.

After the size of the muffle has been determined after total weight,based on a special module of the CAD software the position of positivemodel 10 in a virtual space 32 is determined in accordance with thedisclosure.

In one example, the total volume is to be 1.9 cm³, such that a muffle of200 g is sufficient; a corresponding muffle base with a correspondingmuffle arbor 18 belongs to that.

Positive model 10 in accordance with FIG. 1 have a share in the totalweight of 0.4 cm³, while a total of 6 further positive models, which arenot depicted here, extend in a circular fashion or tapered fashion andstarting from muffle arbor 18 around the latter in virtual space 32 in acorresponding alignment to the alignment of positive model 10.

In the exemplary embodiment depicted, the pressing conception isdetermined for a pressing furnace with annular heating; as a result ofthis, the possible range of angle 30 is restricted to values between,for instance, 25° and 50°, and virtual space 32 is correspondinglysmaller compared with a furnace with underneath heating.

The module now produces, based on a marginal distance to the margin ofthe muffle of, for example, 10 mm, an optimized arrangement of positivemodels 10 in space. By means of elongating conveyor channels 16, dentalrestorations 12 are displaced farther in the direction towards the outercircumference, however keeping in mind the marginal distances. Thedistance from front surface 22 to the upper end of virtual space 32 isalso restricted in the exemplary case, here to 16 mm, and as the defaultlength for the length of the conveyor channel, 3 mm to 8 mm arepredetermined. The total length of dental restoration 12 along axis 14and including the length of conveyor channel 16 amounts, in accordancewith the default from the software module, to 16 mm in this exemplaryembodiment, and the minimum distance of dental restorations 12 from eachother amounts to 3 mm.

The selection of angle 30 results in the primary arrangement within athermal corridor which has a similar temperature range. The alignment ofdental restoration 16 with relation to axis 14 also contributes to this,and so does the selection of docking site 34 too. Angle 30 is determinedin accordance with the alignment of the isothermal corridor specificallyfor the furnace.

In the exemplary embodiment depicted, docking site 34 has been selectedwhere the wall thickness of positive model 10 and dental restoration 12,respectively, is at its maximum, in the exemplary case at a mesio-buccalcusp. The alignment of dental restoration 12 with relation to axis 14 isnow done in such a fashion that a virtual axis 36 of the dentalrestoration, which extends through this from the position of the maximumwall thickness to the position of the dental restoration which isfarthest away (i.e. the maximum longitudinal extension of the latter)coincides with axis 14 of conveyor channel 16, and insofar extends inelongation of the latter. As can be taken from FIG. 2 in comparison withFIG. 1, no co-axial, i.e. exactly coinciding, arrangement is meantherewith, but rather an elongation, for instance with a possible angulardeviation of 15°, wherein with regards to optimization reference isinsofar made to the subsequent description.

Based on the marginal conditions existing insofar, conveyor channel 16is now selected from the library of conveyor channels, and with the helpof the module, the overall arrangement of positive models 10 includingconveyor channels 16 is thus determined.

In a shaping step, the overall arrangement of positive models 10 andconveyor channels 16 is now produced by means of rapid prototyping,which—at least in the present case—is of tree-shaped arrangement.

The creation of the arrangement of positive models is done with the helpof a material which is removable without leaving residues, such aspolyacrylics or also any other suitable polymer which is suitable forrapid-prototyping procession and is characterized by particularly goodshape accuracy.

When using the technology of stereolithography, thus an accuracy ofmanufacture of, for example, 50 μm can be guaranteed, which meets allrequirements.

As can be taken from FIG. 1, the basal surface of the object extends ina downward/outward direction in relation to muffle arbor 18. Thearrangement of dental restorations 12 and positive models 10,respectively, in a top view from above is done principally similar to acake, such that the smallest width of positive models 10 is directedtowards the inside, i.e. in the direction facing pressing channel axis24.

The basic alignment of positive models 10 is done in the flow direction,i.e. corresponding to the elongation of axis 14.

In accordance with FIG. 2, virtual axis 36 of the dental restoration isslightly inclined in relation to axis 14 of conveyor channel 16. Hereby,is taken into account to minimize the re-direction of flow, such thatthe main flow of fluid dental material through the corresponding cavityhappens slightly underneath the longitudinal fissure of the molar there,but in any case one stronger approximated to the occlusal direction thanis visible from FIG. 1. In the direction not visible from FIGS. 1 and 2,i.e. transverse to the drawing layer, the alignment is done in that waythat each of the main flow directions extends through the crown centerin any case.

As is also visible from FIG. 2, conveyor channel 16 extends startingfrom a position of front surface 22 lying rather far towards theoutside. It is quite short, in the exemplary case only 3 mm, wherein itis to be understood that also a larger length of the conveyor channel ispossible if a higher number of objects are to be accommodated in virtualspace 32.

Larger lengths of the conveyor channels have, as is known, a larger flowresistance due to the existing wall friction. In order to compensate forthis, the diameter of the conveyor channel is then enlarged inaccordance with the defaults of the conveyor channel library.

While the positioning in accordance with FIGS. 1 and 2 intends that theocclusal surface is positioned inside (i.e. adjacent to) pressingchannel axis 24, and accordingly the basal surface in theoutward/downward direction, it is also possible to reverse thisarrangement. This alternative arrangement may be favorable in case of amere annular heating of the pressing furnace since then the area oflarger mass of the dental restoration lies within the area of highertemperatures. In addition, the tendency of the muffle to form cracks isreduced in those cases in which round surfaces extend in parallel withthe walls, and in any case no sharp edges.

It is visible from FIG. 3 in what fashion a crown for a front tooth canextend. With this solution, only one single dental restoration isprovided in a 100-g muffle, and due to the low total volume of only 0.3cm³ it is intended to put into practice a dummy channel 40 as anadditional conveyor channel 16, which—created also by means of rapidprototyping—extends towards conveyor channel 16 of dental restoration10.

From FIG. 3—and further Figures—it is also visible that radii 42, 44 areprovided on the input side of the positive model, which are selectedwith respect to the flow and also prevent burrs of plaster, which wouldotherwise exist there, from breaking off as a result of the compressionpressure and contaminating the dental restoration.

As is visible from FIG. 3, on front surface 22 of muffle arbor 18, aconveyor base 46 is formed which is also produced by means of rapidprototyping. Conveyor base 46 creates the connection between thedifferent conveyor channels 16, and at the same time abuts on frontsurface 22 or is anchored there with the help of means of positiveconnection or with the help of an adhesive bond.

Docking site 34 is provided, in the arrangement in accordance with FIG.3, in the incisal area, approximately centrally. This results in amaximized length of virtual axis 36 in such a fashion that it extendsessentially in elongation of axis 14.

In this exemplary embodiment, stereolithography may be employed forrapid prototyping. This does not allow any negative layers, such thatfor technical reasons a displacement of conveyor channel 16 in adirection radially outwards—in relation to axis 24—results. As a result,docking site 34 is displaced into the a proximal area compared with FIG.3, and axis 36 extends in a more inclined fashion than with FIG. 3towards axis 14 of conveyor channel 16.

From FIG. 4, a correspondingly widened conveyor base 46 can be taken,and also in what fashion the material of conveyor base 46 can passthrough an opening 48 in muffle arbor 18 and engage with it in order toput into practice a safe fixation of conveyor base 46.

In FIG. 5, the arrangement of a bridge 49 as a dental restoration isdepicted. Conveyor channels 16 extend towards abutment teeth 50 and 52in its occlusal area, while bridge segment 54 remains free of anyconveyor channels.

Here as well, virtual axes 36 extend through the longest possibleextension of abutment teeth 52 in elongation of axes 14 of conveyorchannels 16. As a result of the higher volume of the dental restorationand its weight, respectively, only a 200 g muffle can be used here, andthe conveyor channels are elongated to 5 mm in view of the morevoluminous dimensioning.

Putting into practice a bridge does not exclude that at the same timeand in the same muffle, single-tooth dental restorations or theirpositive models can be formed respectively. For example, a dentalrestoration 12 in accordance with FIG. 6 can be shaped at a differentangular position than bridge 49 in accordance with FIG. 5 at the sametime.

From FIG. 7, another arrangement of a dental restoration 12, which is aside tooth crown, in relation to its conveyor channel 16 can be taken.

As docking site 34, mesio-palatinal cusps 58 are selected, and the CADsoftware module rotates dental restoration 12 and positive model 10,respectively, in such a fashion that length L of virtual axis 36 throughdental restoration 12 is maximized.

When the dental material flows in, the filling process is done startingfrom the docking site in the flow direction essentially with a uniformfront of dental material. This results in that basal area 62 is filledwith dental material before area 64 is filled which is farthest awayfrom docking site 34 and is also basal, however is positioned slightlymore cervically.

The front of dental ceramic material therefore experiences someresistance first in area 62 which then gradually increases until alsoarea 64 has been filled. This somewhat balanced increase in pressure isfavorable for two reasons: on the one hand, it makes possible to reducepressure slightly before the actual filling has taken place, in order toprevent an abrupt pressure peak when the filling process is completed.On the other hand, the risk of cracks in the muffle due to a pressuresurge towards the end of the filling process is reduced, such that theend of the filling process is balanced.

From FIG. 8, it can be taken in what fashion another dental restoration12 can extend in space. A tapered isothermal corridor 70 is depictedschematically, within which the multitude of dental restorations 12, oneof which is depicted in FIG. 8, extend. Front surface 22 is adjacent tolower end 72 of corridor 70, and the upper end is formed by the upperend of virtual space 32.

Around each dental restoration 12 there extends an envelope space 74which serves for the purpose of keeping the distance and prevents dentalrestoration 12 from being pressed too close to neighboring dentalrestorations. This is depicted schematically as a rectangle in FIG. 8,in practice however, the smallest possible space which keeps a distanceof 3 mm or 2 mm to dental restoration 12.

As can be taken from FIG. 8 with positive model 10 provided in the formof an inlay there, docking site 34 is attached in the upper third at thethickest position of the inlay. Axis 36 is positioned, maximizing lengthL, in elongation of an axis of conveyor 16 which is not depicted here.The flow direction of the front of dental ceramic material generallyextends centrally of the central fissure.

From FIG. 9, a corresponding alignment of a side tooth crown 49 applyingthree coordinate systems can be taken by way of example.

Based on muffle arbor 18 which forms the base of the first coordinatesystem, an isothermal corridor is calculated by the mold, as atrajectory path, along which dental restorations 12 are supposed toextend. At the same time, the possible arrangements of the dentalrestorations are restricted by virtual space 32.

Starting from muffle arbor 18, conveyor channels 16 extend at an angleof 45° to 60° to the horizontal since an annular heating is employedhere.

The third coordinate system is spanned over envelope space 74 of crown49, which is again depicted as a rectangle here, but in fact is anenvelope of the dental restoration.

Flow direction L of the dental ceramic material through the cavitiescreated by positive model 10 is in elongation of the axes of conveyorchannels 16, however inclined at an angle of 12° compared with these.

At the bridge, the abutment is done in a basically known fashion at theincisal surfaces, which is again at the thickest position of each crownthat forms docking site 34.

In the exemplary embodiment depicted, the length of conveyor channels 16amounts to about half of length L of virtual axis 36. It is to beunderstood that this value can be widely adapted to the requirements andtends to be slightly larger with smaller dental restorations andslightly smaller with larger ones.

EXEMPLARY EMBODIMENTS

Example 1: A process for manufacturing a dental restoration:

-   -   in which, based on a scanning result of a mouth situation with        the help of a CAD software, a dental restoration (12) is        designed and is produced as a positive model (10) in a shaping        step in a material that is removable without leaving residues,        such as wax or polyacrylics, by means of removing or in an        additive fashion, for instance by means of rapid prototyping,    -   which positive model (10) is demolded and removed with the help        of a muffle in a basically known fashion, and which muffle is        provided with a pressing channel (20) which is connected via a        conveyor channel (16) with a cavity for the dental restoration        (12) corresponding to the positive model (10),    -   wherein the blank inserted into the pressing channel (20) is        heated and is subjected to pressure, such that it is deformed        and dental material for shaping the dental restoration (12)        flows into the cavity through the conveyor channel (16) and        fills the former, characterized in that    -   in the shaping step or subsequent to that, based on the        dimensions of the muffle in relation to the size and shape of        the positive model (10) or the positive models (10), at least        one conveyor channel (16) is automatically produced for each        positive model (10) with the help of a module of the CAD        software,    -   wherein the module defines a virtual inside space within the        muffle for arrangement of the dental restoration (12) inside        that,    -   wherein the conveyor channel (16) extends at an angle (30) of        between 0° and 130°, in relation to the axis (14, 24) of the        pressing channel (20) in an inclined fashion away from that, in        particular essentially along an isotherm inside the muffle, and    -   wherein the position with the largest wall thickness of the        positive model (10) is selected as a docking site (34), and the        module positions the positive model (10) in relation to the        conveyor channel (16) in such a fashion that it extends in        elongation of the axis (14, 24) of the conveyor channel (16) and        the length of the virtual axis (14, 24) through the positive        model (10) is maximized.

Example 2: The process in accordance with Example 1, characterized inthat the module determines, based on the shape of the dental restoration(12) and thus of the positive model (10), starting from the thickestposition, i.e. the position with the largest wall thickness of that, aprimary flow direction for the dental material as being that directionin which the cross-section of the flow in a pre-determined distance fromthe thickest position is largest, and that the longest virtual axis (36)through the positive model (10) in elongation of the conveyor channelaxis in accordance with Example 1, however deviating in the direction ofthe primary flow direction, is determined.

Example 3: The process in accordance with one of the preceding Examples,characterized in that the alignment of the dental restoration (12)itself and thus of the positive model (10) itself within the muffle aredetermined by the module in such a fashion that their largestlongitudinal extension essentially extends along an isotherm.

Example 4: The process in accordance with one of the preceding Examples,characterized in that if a number of dental restorations (12) aremanufactured at the same time, those are positioned essentially alongthe envelope curve of a cone or taper and equally spread around thepressing channel (20) which essentially terminates at the peak of thatcone or taper.

Example 5: The process in accordance with one of the preceding Examples,characterized in that the conveyor channels are provided with radii (42,44) and/or constant transitions both on the input side, i.e. in thedirection towards the pressing channel (20), and on the output side,i.e. in the direction towards the dental restoration (12).

Example 6: The process in accordance with one of the preceding Examples,characterized in that the conveyor channel (16) which is determined bythe module determines the alignment of the dental restoration (12) withthe help of its axis (14, 24) elongated by the dental restoration (12),and that the alignment of the dental restoration (12) is selected suchthat the penetration length of the elongated conveyor channel (16)through the dental restoration (12) is maximized.

Example 7: The process in accordance with one of the preceding Examples,characterized in that the dental restoration (12) is formed as a crownor a bridge (49) and the basal area of the crown (49) extends inelongation of a pressing channel axis (24) with its open side away fromthe pressing channel (20).

Example 8: The process in accordance with one of Examples 5 or 6,characterized in that the dental restoration (12) is formed as aprefacette or a veneer and the basal area of the prefacette or theveneer extends in such a fashion that it points radially outwards inrelation to a pressing channel axis (24).

Example 9: The process in accordance with one of the preceding Examples,characterized in that the alignment of the dental restoration (12) withrespect to the conveyor channel axis is selected such that theelongation of the conveyor channel axis through the dental restoration(12) extends through the center of mass of the dental restoration (12)if the conveyor channel axis is positioned at the thickest position ofthe dental restoration (12).

Example 10: The process in accordance with one of the precedingExamples, characterized in that the module connects the conveyor channel(16), in relation to the outside surfaces of the dental restoration(12), in an eccentric or off-center fashion, in particular essentiallyin elongation of a labial or buccal surface.

Example 11: The process in accordance with one of the precedingExamples, characterized in that the length of the conveyor channel (16)is determined by the module depending on the size and the weight of thedental restoration (12), in particular with larger dental restorations(12), such as molars, crowns (49) or front-teeth crowns for the upperjaw with a length of 30% to 50% of the length of the main extensionaldirection of the dental restoration (12), and with smaller dentalrestorations (12), such as front-teeth crowns for the lower jaw with alength of 40% to 65% of the length of the main extensional direction ofthe dental restorations (12).

Example 12: The process in accordance with one of the precedingExamples, characterized in that, if a number of dental restorations (12)are arranged in one muffle, the module determines the conveyor channelsto those in such a fashion that the dental restorations (12) arearranged at regular intervals, which is within an isothermal corridor,and if imaginary connecting lines are created, span between these apolyhedron approximating a taper or cone.

Example 13: The process in accordance with one of the precedingExamples, characterized in that the module accesses a conveyor channellibrary which indicates different profile designs, lengths, dockingpoints and angles (30) of conveyor channels based on sizes and types ofdental restorations (12), and that the module, based on these values,determines or suggests the conveyor channels with regards to theirlengths, their diameters and their angles (30).

Example 14: The process in accordance with one of the precedingExamples, characterized in that the virtual inside space for theprovision of the positioning of the dental restoration (12) within themuffle is dependent on the size of the muffle and releases a placingspace of the dental restoration (12) within the muffle in such a fashionthat the dental restoration (12) keeps a distance from the muffle of atleast 2 mm, in particular of 10 mm, with respect to the outside wall ofthe muffle and the height of the virtual inside space is lower in aradially inwardly direction than in a radially outwardly direction.

Example 15: The process in accordance with one of the precedingExamples, characterized in that the positive model (10) is manufacturedwith the help of a milling process and the milling blank is formed as acylinder with a cylinder height corresponding to the virtual space (32)of between 15 mm and 50 mm, in particular about 40 mm.

Example 16: The process in accordance with one of the precedingExamples, characterized in that at least one conveyor channel (16) isformed as a dummy channel (40), i.e. without a dental restoration (12).

Example 17: The process in accordance with one of the precedingExamples, characterized in that the length and thickness of eachconveyor channel (16) relative to the other conveyor channels is set insuch a fashion that it is adapted to the volume of its associated dentalrestoration (12), which is in such a fashion that during pressing thecomplete filling of the dental restoration (12) is done at the sametime, i.e. that conveyor channels for larger dental restorations (12)are set for a lower flow resistance, and conveyor channels for smallerdental restorations (12) are set for a larger flow resistance, and thatin particular each of the flow resistances of the conveyor channels isselected such that it is proportional to the weight of the associateddental restorations (12).

Example 18: A dental ceramics production device, with a CAD/CAM devicefor providing a pressing mold for manufacturing a dental ceramics,wherein a CAD software of this, based on a scanning result of a mouthsituation, determines the shape of the dental restoration (12), andwherein a CAM device of this determines the configuration of the dentalrestoration (12) with the help of an expendable muffle, characterized inthat the CAD software is provided with a module which automaticallydetermines the arrangement of the angle and the dimensions of a conveyorchannel (16) between a central pressing channel (20) and a cavity forshaping the dental restoration (12) inside a virtual inside space withinthe muffle and determines the work angle of the dental restoration (12)in relation to the conveyor channel axis of the associated conveyorchannel (16) at a docking site (34) of the dental restoration (12) atthe conveyor channel (16), which has been selected at the thickestposition of the dental restoration (12), in such a fashion that theelongation of the conveyor channel axis extends through the largestpossible length of the dental restoration (12) starting from thethickest position, in particular based on a pre-set library of shapes ofdental restorations (12) and/or conveyor channels.

Example 19: The dental ceramics production device in accordance withExample 18, characterized in that the docking site (34) of the dentalrestoration (12) at the conveyor channel (16) is selected by the moduleat the position at which a ball with the largest possible diameter fitsinto the dental restoration (12), wherein the elongation of the axis(14, 24) of the conveyor channel (16) extends in particular essentiallythrough the center of this ball.

Example 20: The dental ceramics production device in accordance with oneof Examples 18 or 19, characterized in that each dental restoration (12)is determined by the module in the virtual space (32) with regards toits arrangement and alignment in such a fashion that it has a marginaldistance both from the outside wall of the muffle and from theneighboring dental restoration (12) which does not exceed apre-determined value which in particular amounts to several millimeters.

Example 21: The dental ceramics production device in accordance with oneof Examples 18 to 20, characterized in that the docking site (34) of thedental restoration (12) at the conveyor channel (16) in the verticalprojection—in relation to the muffle—is selected in such a fashion thata narrow position of the dental restoration (12) is arranged radiallyinwards, i.e. adjacent to the pressing channel (20), and a widerposition further outside radially, principally similar to a cake.

Example 22: The dental ceramics production device in accordance with oneof Examples 18 to 21, characterized in that the conveyor channel (16)and/or the dental restoration (12) is provided with a code or anidentification at a basal or at least a covered position, whichfacilitates the association with the order concerned and/or the patientconcerned.

Example 23: The dental ceramics production device in accordance with oneof Examples 18 to 22, characterized in that the dental restoration (12)is provided with a constant and layer-by-layer construction which issuitable for stereolithography, in particular with an envelope curvewhose slope is always larger than or equal zero over its entireextension, observed each starting from docking site (34) of the dentalrestoration (12) concerned in the lateral view of that, or observed inthe direction of the pressing channel axis.

Example 24: The dental ceramics production device in accordance with oneof the preceding Examples, characterized in that the CAM device uses asthe zero position of the virtual inside space the front surface (22) ofthe pressing channel (20) and polymerizes a conveyor channel basedirectly to that front surface (22) away from which the conveyorschannels extend.

Although the present disclosure has been described with respect to oneor more particular embodiments, it will be understood that otherembodiments of the present disclosure may be made without departing fromthe spirit and scope of the present disclosure. Hence, the presentdisclosure is deemed limited only by the appended claims and thereasonable interpretation thereof

What is claimed is:
 1. A method for manufacturing a dental restorationfor a patient comprising: designing a dental restoration based on a scanof the patient's mouth, using a CAD software module; producing apositive model of the dental restoration using a material that isremovable from a mold without leaving a residue; producing, using theCAD software module, at least one conveyor channel for the positivemodel based on the dimensions of a muffle in relation to the size andshape of the positive model, wherein the conveyor channel is determinedby defining a space within the muffle for arrangement of the dentalrestoration; removing the positive model using the muffle, wherein themuffle has a pressing channel which is connected via a conveyor channelwith a cavity for the dental restoration corresponding to the positivemodel; inserting a blank of dental material into the pressing channel;and heating and applying pressure to the blank such that the blank isdeformed and dental material for shaping the dental restoration flowsthrough the conveyor channel and fills the cavity; wherein the conveyorchannel extends at an angle of between 0° and 130° away from an axis ofthe pressing channel, the axis being located essentially along anisotherm inside the muffle; and wherein a docking site is selected basedon a position with the greatest wall thickness of the positive model,and the CAD software module positions the positive model in relation tothe conveyor channel to elongate the axis of the conveyor channel andthat the length of a virtual axis through the positive model ismaximized.
 2. The method of claim 1, wherein the CAD software moduledetermines, based on the shape of the positive model, starting from theposition with the greatest wall thickness of the positive model, aprimary flow direction for the dental material in which thecross-section of the flow in a pre-determined distance from the thickestposition is greatest, and that the maximized virtual axis through thepositive model deviates in the primary flow direction.
 3. The method ofclaim 1, wherein the arrangement of the dental restoration within themuffle are determined by the CAD software module in such a fashion thatthe greatest longitudinal extension of the dental restorationessentially extends along an isotherm.
 4. The method of claim 1, whereinthat if a plurality of dental restorations are manufactured at the sametime, the plurality of dental restorations are positioned essentiallyalong the envelope curve of a cone or taper and equally spread aroundthe pressing channel which essentially terminates at the peak of thecone or taper.
 5. The method of claim 1, wherein the conveyor channel isprovided with radii and/or constant transitions in the direction towardsthe pressing channel, and in the direction towards the dentalrestoration.
 6. The method of claim 1, wherein the conveyor channeldetermines the alignment of the dental restoration, and an alignment ofthe dental restoration is determined such that a penetration length ofthe conveyor channel through the dental restoration is maximized.
 7. Themethod of claim 1, wherein the dental restoration is formed as a crownor a bridge and the basal area of the crown extends in elongation of apressing channel axis with an open side away from the pressing channel.8. The method of claim 5, wherein the dental restoration is formed as aprefacette or a veneer and the basal area of the prefacette or theveneer extends such that it points radially outwards in relation to apressing channel axis.
 9. The method of claim 1, wherein an alignment ofthe dental restoration with respect to the conveyor channel axis isselected such that the elongation of the conveyor channel axis throughthe dental restoration extends through the center of mass of the dentalrestoration when the conveyor channel axis is positioned at the thickestposition of the dental restoration.
 10. The method of claim 1, where theCAD software module connects the conveyor channel, in relation to theoutside surfaces of the dental restoration, in an eccentric oroff-center fashion.
 11. The method of claim 1, wherein the length of theconveyor channel is determined by the CAD software module depending onthe size and the weight of the dental restoration.
 12. The method ofclaim 1, wherein if a number of dental restorations are arranged in onemuffle, the CAD software module determines the conveyor channels to thedental restorations such that the dental restorations are arranged atregular intervals within an isothermal corridor such that thearrangement of dental restorations approximates a taper or cone.
 13. Themethod of claim 1, wherein the CAD software module accesses a conveyorchannel library which indicates different profile designs, lengths,docking points and angles of conveyor channels based on sizes and typesof dental restorations, and that the CAD software module, based on thesevalues, determines or suggests the conveyor channels with regards totheir lengths, their diameters, and their angles.
 14. The method ofclaim 1, wherein the virtual inside is dependent on the size of themuffle and releases a placing space of the dental restoration within themuffle such that the dental restoration keeps a distance from the muffleof at least 2 mm with respect to the outside wall of the muffle and theheight of the virtual inside space is lower in a radially inwardlydirection than in a radially outwardly direction.
 15. The method ofclaim 1, wherein the positive model is manufactured by a milling processand a milling blank is formed as a cylinder with a cylinder heightcorresponding to the virtual space of between 15 mm and 50 mm.
 16. Themethod of claim 1, wherein at least one conveyor channel is formed as adummy channel without an associated dental restoration.
 17. The methodof claim 1, wherein the length and thickness of each conveyor channelrelative to the other conveyor channels is selected such that it isadapted to the volume of its associated dental restoration.
 18. A dentalceramics production device comprising: a CAD/CAM device for providing apressing mold for manufacturing a dental ceramics; and a CAD softwaremodule executed by the CAD/CAM device, the CAD software moduleconfigured to: determine the shape of a dental restoration, based on ascanning result of a mouth of a patient; determine the configuration ofthe dental restoration using an expendable muffle; determine thearrangement of an angle and dimensions of a conveyor channel between acentral pressing channel and a cavity for shaping the dental restorationinside a virtual inside space within the muffle; and determine the workangle of the dental restoration in relation to a conveyor channel axisof the associated conveyor channel at a docking site of the dentalrestoration at the conveyor channel, the docking site positioned at thethickest position of the dental restoration, such that an elongation ofthe conveyor channel axis extends through the largest possible length ofthe dental restoration starting from the thickest position, inparticular based on a pre-set library of shapes of dental restorationsand/or conveyor channels.
 19. The device of claim 18, wherein thedocking site of the dental restoration at the conveyor channel isselected by the CAD software module at the position at which a ball withthe largest possible diameter fits into the dental restoration, whereinan elongation of the axis of the conveyor channel extends in particularessentially through the center of this ball.
 20. The device of claim 18,wherein each dental restoration is determined by the CAD software modulein the virtual space with regards to its arrangement and alignment suchthat it has a marginal distance both from the outside wall of the muffleand from the neighboring dental restoration which does not exceed apre-determined value.
 21. The device of claim 18, wherein the dockingsite of the dental restoration at the conveyor channel in a verticalprojection in relation to the muffle is selected in such a fashion thata narrow position of the dental restoration is arranged radially inwardsand a wider position further outside radially.
 22. The device of claim18, wherein the conveyor channel and/or the dental restoration isprovided with a code or an identification at a basal or a coveredposition, which facilitates the association with the order concernedand/or the patient concerned.
 23. The device of claim 18, wherein thedental restoration is provided with a constant and layer-by-layerconstruction which is suitable for stereolithography, in particular withan envelope curve whose slope is always larger than or equal to zeroover its entire extension from docking site of the dental restoration inthe lateral view or observed in the direction of the pressing channelaxis.
 24. The device of claim 18, wherein the CAD/CAM device uses as thezero position of the virtual inside space the front surface of thepressing channel and polymerizes a conveyor channel base directly tothat front surface away from which the conveyors channels extend.